DNA delivery to the mitochondria sites using mitochondrial leader peptide conjugated polyethylenimine

Some genetic diseases are associated with the defects of the mitochondrial genome. Direct DNA delivery to the mitochondrial matrix has been suggested as an approach for mitochondrial gene therapy for these diseases. We hypothesized that a mitochondrial leader peptide (LP) conjugated polyethylenimine (PEI) could deliver DNA to the mitochondrial sites. PEI-LP was synthesized by the conjugation of LP to PEI using disulfide bond. The complex formation of PEI-LP with DNA was confirmed by a gel retardation assay. In this study, DNA was completely retarded at a 0.4/1 PEI-LP/DNA weight ratio. In vitro delivery tests into isolated mitochondria or living cells were performed with rhodamin-labeled DNA and PEI-LP. In vitro cell-free delivery assay with isolated mitochondria showed that PEI-LP/DNA complexes were localized at mitochondria sites. Furthermore, the PEL-LP/DNA complexes were localized at the mitochondrial sites in living cells. However, a control carrier, PEI, did not show this effect. In addition, MTT assay showed that PEI-LP showed lower cytotoxicity than PEI. These results suggest that PEI-LP can deliver DNA to the mitochondrial sites and may be useful for the development of mitochondrial gene therapy.     

Epidermal growth factor receptor-targeted peptide conjugated phospholipid micelles for doxorubicin delivery

Specific targeting of tumor cells to achieve higher drug levels in tumor tissue and to overcome side effects is the major goal in cancer chemotherapy. In this study, we used a tumor targeting peptide, GE11, to conjugate onto the surface of doxorubicin encapsulated phospholipid micelles. The GE11 peptide triggered specific binding to epidermal growth factor receptor (EGFR), leading to enhanced cellular uptake and cytotoxicity in vitro and highly accumulation in the tumors in vivo. The results indicated that GE11 conjugated phospholipid micelles should have potential applications in cancer therapy.     

The effect of dual ligand-targeted micelles on the delivery and efficacy of poorly soluble drug for cancer therapy

Abstract

We prepared and evaluated transferrin (Tf) and monoclonal antibody (mAb) 2C5-modified dual ligand-targeted poly(ethylene glycol)–phosphatidylethanolamine micelles loaded with a poorly soluble drug, R547 (a selective adenosine triphosphate-competitive cyclin-dependent kinase inhibitor) for enhancement of targeting efficiency and cytotoxicity in vitro and in vivo to A2780 ovarian carcinoma compared to single ligand-targeted micelles. Micellar solubilization significantly improved the solubility of R547 from 1 to 800?μg/mL. The size of modified and non-modified micelles was 13–16?nm. Flow cytometry indicated significantly enhanced cellular association of dual ligand-targeted micelles compared to single ligand-targeted micelles. Confocal microscopy confirmed the Tf receptor-mediated endocytosis of rhodamine-labeled Tf-modified micelles after staining the micelle-treated cells with the endosomal marker Tf–Alexa488. The optimized dual-targeted micelles enhanced cytotoxicity in vitro against A2780 ovarian cancer cells compared to plain and single ligand-targeted micelles. Interestingly, in vivo anti-tumor efficacy was more pronounced for the preparation with a single-targeting ligand (Tf). The specific combination Tf and mAb 2C5 did not yield the expected increase in efficacy as was observed in vitro. This observation suggests that the relationships between targeting ligands in vivo could be more complex than in simplified in vitro systems, and the results of the optimization process should always be verified in vivo.     

Bombesin peptide antagonist for target-selective delivery of liposomal doxorubicin on cancer cells

Purpose: This study addresses novel peptide modified liposomal doxorubicin to specifically target tissues overexpressing bombesin (BN) receptors.

Methods: DOTA-(AEEA)₂-peptides containing the [7–14]bombesin and the new BN-AA1 sequence have been synthesized to compare their binding properties and in serum stabilities. The amphiphilic peptide derivative (MonY-BN-AA1) containing BN-AA1, a hydrophobic moiety, polyethylenglycole (PEG), and diethylenetriaminepentaacetate (DTPA), has been synthesized. Liposomes have been obtained by mixing of MonY-BN-AA1 with 1,2-distearoyl-sn-glycero-3-phosphocholine (DSPC).

Results: Both ¹¹¹In labeled peptide derivatives present nanomolar Kd to PC-3 cells. ¹⁷⁷Lu labeled peptide DOTA-(AEEA)₂-BN-AA1 is very stable (half-life 414.1?h), while DOTA-(AEEA)₂-BN, shows a half-life of 15.5?h. In vivo studies on the therapeutic efficacy of DSPC/MonY-BN-AA1/Dox in comparison to DSPC/MonY-BN/Dox, were performed in PC-3 xenograft bearing mice. Both formulations showed similar tumor growth inhibition (TGI) compared to control animals treated with non-targeted DSPC/Dox liposomes or saline solution. For DSPC/MonY-BN-AA1/Dox the maximum effect was observed 19 days after treatment.

Conclusions: DSPC/MonY-BN-AA1/Dox nanovectors confirm the ability to selectively target and provide therapeutic efficacy in mice. The lack of receptor activation and possible acute biological side effects provided by using the AA1 antagonist bombesin sequence should provide safe working conditions for further development of this class of drug delivery vehicles.     

Prodrugs for improving tumor targetability and efficiency

As the mainstay in the treatment of various cancers for several decades, chemotherapy is successful but still faces challenges including non-selectivity and high toxicity. Improving the selectivity is therefore a critical step to improve the therapeutic efficacy of chemotherapy. Prodrug is one of the most promising approaches to increase the selectivity and efficacy of a chemotherapy drug. The classical prodrug approach is to improve the pharmaceutical properties (solubility, stability, permeability, irritation, distribution, etc.) via a simple chemical modification. This review will focus on various targeted prodrug designs that have been developed to increase the selectivity of chemotherapy drugs. Various tumor-targeting ligands, transporter-associated ligands, and polymers can be incorporated in a prodrug to enhance the tumor uptake. Prodrugs can also be activated by enzymes that are specifically expressed at a higher level in tumors, leading to a selective anti-tumor effect. This can be achieved by conjugating the enzyme to a tumor-specific antibody, or delivering a vector expressing the enzyme into tumor cells.     

Co‐nanoencapsulated doxorubicin and Dz13 control osteosarcoma progression in a murine model

Objectives Chitosan is a green (natural, abundant, biodegradable, biocompatible) biopolymer that can be formulated to encapsulate a variety of therapeutic compounds. This study aimed to investigate chitosan nanoparticles (NPs) as a means of improving delivery of the clinically used anti‐cancer agent doxorubicin (Dox) and the preclinical lead compound Dz13 oligonucleotide together. Methods A novel chitosan NP system encapsulating Dox and Dz13 was designed, biophysically characterised and tested in a clinically relevant model of the metastasising bone tumour, osteosarcoma (OS). Key findings By careful alteration of the concentration of the individual components, a final formulation of Dz13‐Dox NPs (DDNPs) was achieved, with high (>91%) loading of both compounds, which consisted of individual 50‐nm particles forming aggregates as large as 500 nm, with a large positive ζ‐potential. The DDNPs could be stored at various temperatures for a week without loss in activity but were prone to degradation in serum. DDNPs successfully inhibited OS tumour growth more effectively than treatment with NPs of Dz13 and Dox‐chitosan, as well as Dox administered intraperitoneally. Apart from inhibiting tumour growth, DDNPs protected the affected bone from substantial destruction by aggressive tumour growth and reduced the incidence of metastasis to the lungs without causing adverse effects in mice. Conclusion This NP is a promising formulation that could be useful for clinical management of OS.     

Polymeric micelles for targeted tumor therapy of platinum anticancer drugs

Introduction: Platinum anticancer drugs are effective against a wide range of tumors, though their severe adverse effects and resistance remain unresolved. A breakthrough in these drawbacks could be achieved by using polymeric micelles, i.e. nanoassemblies having a drug loaded core and a protective hydrophilic shell, incorporating platinum drugs for tumor-targeted delivery.

Areas covered: The development of cisplatin- (NC-6004) and DACHPt-loaded micelles (NC-4016) has been reviewed, particularly, from the viewpoint of the effect of their structural features on the tumor-targeting efficacy. We have also described new approaches for molecular targeting by installing ligand moieties on the surface of micelles. Moreover, small platinum drugs and platinum drug-loaded nanocarriers are introduced to explain the context for developing platinum drug-loaded polymeric micelles.

Expert opinion: NC-6004 and NC-4016 micelles meet critical structural and functional requirements for achieving safe and effective tumor targeting, enhancing efficacy even against drug resistant cancer cells, and have been translated into human studies, aiming to be the first-of-their-kind in the clinic. Due to their flexible design, polymeric micelles could readily integrate new features based on the knowledge arising from the human clinical trials toward the development of innovative formulations with superior performance.     

Nanoparticle-mediated co-delivery of chemotherapeutic agent and siRNA for combination cancer therapy

Introduction: Cancer is the leading cause of death worldwide. Current cancer treatments in the clinic mainly include chemotherapy, radiotherapy and surgery, with chemotherapy being the most common.

Areas covered: Cancer treatments based on the single ‘magic-bullet’ concept are often associated with limited therapeutic efficacy, unwanted adverse effects, and drug resistance. The combination of multiple drugs is a promising strategy for effective cancer treatment due to the synergistic or additive effects. Small interfering RNA (siRNA) has the ability to knock down the expression of carcinogenic genes or drug efflux transporter genes, paving the way for cancer treatment. Treatment with both a chemotherapeutic agent and siRNA based on nanoparticle (NP)-mediated co-delivery is a promising approach for combination cancer therapy.

Expert opinion: The combination of chemotherapeutic agents and siRNAs for cancer treatment offers the potential to enhance therapeutic efficacy, decrease side effects, and overcome drug resistance. Co-delivery of chemical drug and siRNA in the same NP would be much more effective in cancer therapy than application of chemical agent or siRNA alone. With the development of material science, NPs have come to be the most widely used platform for co-delivery of chemotherapeutic drugs and siRNAs.     

Mitochondrial-targeted penetrating peptide delivery for cancer therapy

Introduction: Mitochondria are promising targeting organelles for anticancer strategies; however, mitochondria are difficult for antineoplastic drugs to recognize and bind. Mitochondria-penetrating peptides (MPPs) are unique tools to gain access to the cell interior and deliver a bioactive cargo into mitochondria. MPPs have combined or delivered a variety of antitumor cargoes and obviously inhibited the tumor growth in vivo and in vitro. MPPs create new opportunities to develop new treatments for cancer.

Areas covered: We review the target sites of mitochondria and the target-penetration mechanism of MPPs, different strategies, and various additional strategies decorated MPPs for tumor cell mitochondria targeting, the decorating mattes including metabolism molecules, RNA, DNA, and protein, which exploited considered as therapeutic combined with MPPs and target in human cancer treatment.

Expert opinion/commentary: Therapeutic selectivity that preferentially targets the mitochondrial abnormalities in cancer cells without toxic impact on normal cells still need to be deepen. Moreover, it needs appropriate study designs for a correct evaluation of the target delivery outcome and the degradation rate of the drug in the cell. Generally, it is optimistic that the advances in mitochondrial targeting drug delivery by MPPs plasticity outlined here will ultimately help to the discovery of new approaches for the prevention and treatment of cancers.     

Hochest染料-荧光分光光度法测定基因治疗非病毒载体中DNA的含量

目的　利用荧光染料Hoechst 332 5 8与DNA结合后 ,荧光强度显著增强的特点 ,建立了基因治疗非病毒载体中DNA的含量测定方法。方法　对Hoechst 332 5 8-DNA溶液进行荧光扫描 ,并建立了标准曲线。分别测定了纳米粒胶体溶液超速冷冻离心后的上清液和用酶消化后的脂质体提取液中DNA的含量。结果　Hoechst332 5 8-DNA溶液的最佳激发波长为 35 3.6nm ,最佳发射波长为 4 5 4 .4nm ,标准曲线的线性范围为 0 .2～ 1.0 μg·ml-1。测得包载DNA纳米粒的平均包封率为 75 .1%± 8.6 %(n =5 ) ,DNA阳离子脂质体的平均抗核酸酶能力为 84 .9%± 7.8% (n =5 )。结论　荧光染料Hoechst332 5 8可用于测定基因治疗非病毒载体中DNA的含量 ,所建立的荧光分光光度法为载基因纳米粒、脂质体制备工艺和质量标准的建立提供了依据。     

Glioma homing peptide-modified PEG-PCL nanoparticles for enhanced anti-glioma therapy

Background: Peptide-mediated drug delivery system (DDS) has been increasingly used to promote on-demand treatment efficacy of cancers. Herein, LTLRWVGLMS (LS10) peptide is selected as the functional ligand for specific glioma-targeting drug delivery. LS10 peptide selectively binds to NG2 proteins that are widely overexpressed in the glioma cells and restricted in normal tissue. LS10 peptide-decorated DDS is expected to hold vast promises in glioma therapy and decrease unwanted side effects.

Methods: LS10 peptide was conjugated on the surface of poly(ethylene glycol)-poly(?-caprolactone) (PEG-PCL) nanoparticles via 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride/N-hydroxysulfosuccinimide coupling reaction. Using U87MG cells as the glioma cell model, cellular uptake, internalization mechanism, cellular cytotoxicity and apoptosis were investigated. 1,1′-Dioctadecyl-3,3,3′,3′-tetramethyl indotricarbocyanine iodide were used as fluorescence probes to investigated in vivo glioma targeting capability of LS10-NP. The glioma therapeutic efficacy of paclitaxel-loaded LS10-NP was studied on glioma-bearing nude mice.

Results: The LS10-NP with size of 119?nm enhanced cellular uptake on U87MG cells, increased cytotoxicity of the loaded paclitaxel (PTX), and improved penetration in 3D U87MG glioma spheres. In vivo biodistribution experiments showed that LS10-NP exhibited the enhanced drug localization at glioma site, which resulted in prolonged survival time of glioma-bearing mice.

Conclusion: Our results indicated that LS10 peptide-modified nanoparticulate DDS could significantly improve the anti-glioma efficacy.     

Combination therapy: Opportunities and challenges for polymer–drug conjugates as anticancer nanomedicines

The discovery of new molecular targets and the subsequent development of novel anticancer agents are opening new possibilities for drug combination therapy as anticancer treatment. Polymer–drug conjugates are well established for the delivery of a single therapeutic agent, but only in very recent years their use has been extended to the delivery of multi-agent therapy. These early studies revealed the therapeutic potential of this application but raised new challenges (namely, drug loading and drugs ratio, characterisation, and development of suitable carriers) that need to be addressed for a successful optimisation of the system towards clinical applications.     

Nanoparticle drug delivery systems: an excellent carrier for tumor peptide vaccines

In the past 40 years, the nanoparticle drug delivery system for tumor peptide vaccines has been widely studied which also reached a splendid result. Nanomaterial can enhance the targeting of vaccines, help vaccines enter the cells and trigger immune response by themselves. They also help in increasing cellular uptake, improving permeability and efficacy. Currently, several categories of nanopreparation, such as liposome, polymeric micelle, polymeric nanoparticle, gold nanoparticle and so on, are proved that they are appropriate for peptide vaccines. This review we discussed the possible mechanisms of nanomaterial’s action on the regulation of immunological functions and several major applications of this advanced drug delivery system for tumor peptide vaccine.     

Injectable poly(organophosphazene) hydrogel system for effective paclitaxel and doxorubicin combination therapy

Abstract

Combination therapy is an important option for gastric cancer which is the second leading cause of cancer-related death worldwide. The administration schedule of cell cycle-specific drugs, such as doxorubicin (DOX) and paclitaxel (PTX), is important for therapeutic efficacy. However, to control the schedule is clinically inconvenient. Additionally, in vitro cytotoxicity tests against human gastric cancer cells (SNU-601) showed that the combination indices (CIs) of DOX and PTX were 1.43 (α?=?0) and 1.90 (α?=?1), respectively, indicating that the DOX and PTX interaction was antagonistic. Thus, based on the finding that the release rate of drugs from poly(organophosphazene) (PPZ) hydrogel is dependent on the hydrophobicity of the drugs, we used injectable PPZ hydrogel in combination therapy. In vivo anticancer activity test in human gastric cancer cell-xenografted mice showed that intratumoral injection with aqueous PPZ solution, containing DOX (15?mg/kg) and PTX (30?mg/kg), resulted in the highest tumor inhibition and safety (no mortality for approximately 3 months) in the experimental groups. Consequently, PPZ hydrogel is expected to be a promising drug delivery system for cell cycle-specific drugs, facilitating the control of their administration schedule for effective combination therapy.     

Lipid-polymer hybrid nanoparticle with cell-distinct drug release for treatment of stemness-derived resistant tumor

Drug resistance presents one of the major causes for the failure of cancer chemotherapy.Cancer stem-like cells(CSCs),a population of self-renewal cells with high tumorigenicity and innate chemoresistance,can survive conventional chemotherapy and generate increased resistance.Here,we develop a lipid-polymer hybrid nanoparticle for co-delivery and cell-distinct release of the differentiation-inducing agent,all-trans retinoic acid and the chemotherapeutic drug,doxorubicin to overcome the CSC-associ...     

A new peptide ligand for colon cancer targeted delivery of micelles

Abstract

Ligands are an imperative part of targeted drug delivery systems, and choosing a ligand with high affinity is a subject of considerable interest. In this study, we first synthesized a 12-residue peptide (TK) that interacts with integrin α₆β₁ overexpressed on colonic cancer cells. The molecular binding affinity assay indicated that TK had a high binding affinity for integrin α₆β₁. The results of cellular and tumor spheroid uptake suggested that TK peptide not only increases Caco-2 cells uptake, but also effectively increases penetration of the tumor spheroids. TK-conjugated PEG-PLA was synthesized to prepare a novel PEG-PLA micelles loading DOX or coumarin-6 (TK-MS/DOX or TK-MS/C6). The obtained TK-MS/DOX exhibited uniform, spherical shape with a size of 23.80?±?0.32?nm and zeta potential of 12.21?±?0.31 mV. The release behavior of DOX from micelles were observed no significant changes after TK modification, however, the release profile exhibited pH-sensitive properties. Compared with MS/DOX, TK-MS/DOX exhibited significantly stronger cytotoxicity for Caco-2. Confocal laser microscopy and flow cytometry data further indicated that the targeting micelles not only had higher uptake by Caco-2 cells, but also more effectively penetrated the tumor spheroids. Therefore, TK peptide appears to be suitable as a targeting ligand with potential applications in colonic targeted therapy.     

Single-walled carbon nanotube-loaded doxorubicin and Gd-DTPA for targeted drug delivery and magnetic resonance imaging

An aspargine-glycine-arginine (NGR) peptide modified single-walled carbon nanotubes (SWCNTs) system, developed by a simple non-covalent approach, could be loaded with the anticancer drug doxorubicin (DOX) and magnetic resonance imaging (MRI) contrast agent gadolinium-diethylenetriamine pentaacetic acid (Gd-DTPA). This DOX- and Gd-DTPA-loaded NGR functionalized SWCNTs (DOX/NGR-SWCNTs/Gd-DPTA) retained both cytotoxicity of DOX and MRI contrast effect of Gd-DPTA. This drug delivery system showed excellent stability in physiological solutions. This DOX/NGR-SWCNTs/Gd-DPTA system could accumulate in tumors and enter into tumor cells, which facilitated combination chemotherapy with diagnosis of tumor in one system. An excellent in vitro anti-tumor effect was shown in MCF-7 cells treated by DOX/NGR-SWCNTs/Gd-DPTA, compared with DOX solution, DOX/SWCNTs and DOX/SWCNTs/Gd-DPTA. In vivo data of DOX/NGR-SWCNTs/Gd-DPTA group in tumor-bearing mice further confirmed that this system performed much higher tumor targeting capacity and anti-tumor efficacy than other control groups.     

Peptide-based cationic molecules for the production of positive charged liposomes and micelles

This paper describes the synthesis and the physico-chemical characterization of cationic peptides (CPs) for possible application as non-viral gene delivery systems. Particularly, the production of cationic liposomes and micelle solutions was considered. Liposomes were prepared by REV-phase and extrusion presenting an average diameter reflecting the pore size of the membrane used for the extrusion. After DNA complexation the mean diameter of complexes decreased by increasing the number of positive charges. The non-complexed liposome preparations showed a net positive zeta potential comprised between 17.8–30 mV. After adding Defibrotide (DFT) to liposomes (at a 1:4?±?molar ratio) the zeta potential fell down to a net negative value indicating the formation of the ionic complex. Concerning micelles, before complexation it was not possible to measure their size by PCS. However, after DFT complexation the size of complexes highly increased. In addition, as previously seen for liposomes, before complexation, the five CPs solutions showed a positive zeta potential ranging from 10–17.8 mV, while after addition of DFT the zeta potential fell to negative values. Concerning toxicity studies, in general CP-liposomes displayed a lower toxicity towards K562 cells as compared to the corresponding CP-solution. Taking into account these results, the studied CPs could be efficiently used to obtain both cationic liposomes and micelles. Moreover they are able to complex DNA with different interaction strength, depending on the type of peptide-based cationic molecule used.     

GLP-1 peptide analogs for targeting pancreatic beta cells

Loss or dysfunction of the pancreatic beta cells or insulin receptors leads to diabetes mellitus (DM). This usually occurs over many years; therefore, the development of methods for the timely detection and clinical intervention are vital to prevent the development of this disease. Glucagon-like peptide-1 receptor (GLP-1R) is the receptor of GLP-1, an incretin hormone that causes insulin secretion in a glucose-dependent manner. GLP-1R is highly expressed on the surface of pancreatic beta cells, providing a potential target for bioimaging. In this review, we provide an overview of various strategies, such as the development of GLP-1R agonists (e.g., exendin-4), and GLP-1 sequence modifications for GLP-1R targeting for the diagnosis and treatment of pancreatic beta cell disorders. We also discuss the challenges of targeting pancreatic beta cells and strategies to address such challenges.     

Probing the binding of the coumarin drugs using peptide fragments of DNA gyrase B protein

Abstract: Bacterial DNA gyrase, has been identified as the target of several antibacterial agents, including the coumarin drugs. The coumarins inhibit the gyrase action by competitive binding to the ATP‐binding site of DNA gyrase B (GyrB) protein. The high in vitro inhibitory potency of coumarins against DNA gyrase reactions has raised interest in studies on coumarin–gyrase interactions. In this context, a series of low‐molecular weight peptides, including the coumarin resistance‐determining region of subunit B of Escherichia coli gyrase, has been designed and synthesized. The first peptide model was built using the natural fragment 131–146 of GyrB and was able to bind to novobiocin (K_a = 1.8 ± 0.2 × 10⁵/m ) and ATP (K_a = 1.9 ± 0.4 × 10³/m ). To build the other sequences, changes in the Arg¹³⁶ residue were introduced so that the binding to the drug was progressively reduced with the hydrophobicity of this residue (K_a = 1.3 ± 0.1 × 10⁵/m and 1.0 ± 0.2 × 10⁵/m for Ser and His, respectively). No binding was observed for the change Arg¹³⁶ to Leu. In contrast, the binding to ATP was not altered, independently of the changes promoted. On the contrary, for peptide–coumarin and peptide–ATP complexes, Mg²⁺ appears to modulate the binding process. Our results demonstrate the crucial role of Arg¹³⁶ residue for the stability of coumarin–gyrase complex as well as suggest a different binding site for ATP and in both cases the interactions are mediated by magnesium ions.